prob-fx: A library for modular probabilistic modelling

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A library for probabilistic programming using algebraic effects. The emphasis is on modular and reusable definitions of probabilistic models, and also compositional implementation of model execution (inference) in terms of effect handlers.


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Versions [RSS] 0.1.0.0, 0.1.0.1, 0.1.0.2 (info)
Change log CHANGELOG.md
Dependencies base (>=4.11 && <=4.17), containers (>=0.6.0 && <0.7), criterion (>=1.5.13 && <1.6), deepseq (>=1.4.4 && <1.5), dirichlet (>=0.1.0 && <0.2), extensible (>=0.9 && <0.10), ghc-prim (>=0.5.3 && <0.8), lens (>=5.1.1 && <5.2), log-domain (>=0.13.2 && <0.14), membership (>=0.0.1 && <0.1), mtl (>=2.2.2 && <2.3), mwc-probability (>=2.3.1 && <2.4), mwc-random (>=0.15.0 && <0.16), primitive (>=0.7.4 && <0.8), prob-fx, random (>=1.2.1 && <1.3), split (>=0.2.3 && <0.3), statistics (>=0.16.1 && <0.17), transformers (>=0.5.6 && <0.6), vector (>=0.12.3 && <0.13) [details]
Tested with ghc ==8.6.5, ghc ==8.8.4, ghc ==8.10.4, ghc ==9.0.1
License BSD-3-Clause
Copyright 2022 Minh Nguyen
Author Minh Nguyen
Maintainer minhnguyen1995@googlemail.com
Revised Revision 1 made by minnguyen at 2022-07-17T17:07:18Z
Category Statistics
Home page https://github.com/min-nguyen/prob-fx
Uploaded by minnguyen at 2022-07-17T14:47:04Z
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Executables prob-fx
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Readme for prob-fx-0.1.0.2

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ProbFX

Prelude

ProbFX is a library for probabilistic programming using algebraic effects that implements the paper Modular Probabilistic Models via Algebraic Effects -- this paper provides a comprehensive motivation and walkthrough of this library. To have a more interactive and visual play-around with ProbFX, please see the artifact branch: this corresponds parts of the paper to the implementation, and also provides an executable version of ProbFX as a script.

Description

ProbFx is a PPL that places emphasis on being able to define modular and reusable probabilistic models, where the decision to sample or observe against a random variable or distribution of a model is delayed until the point of execution; this allows a model to be defined just once and then reused for a variety of applications. We also implement a compositional approach towards model execution (inference) by using effect handlers.

Building and executing models

A large number of example ProbFX programs are documented in the examples directory, showing how to define and then execute a probabilistic model.

In general, the process is:

  1. Define an appropriate model of type Model env es a, and (optionally) a corresponding model environment type env.

    For example, a logistic regression model that takes a list of Doubles as inputs and generates a list of Bools, modelling the probability of an event occurring or not:

    -- | The model environment type, for readability purposes
    type LogRegrEnv =
      '[  "y" ':= Bool,   -- ^ output
          "m" ':= Double, -- ^ mean
          "b" ':= Double  -- ^ intercept
      ]
    
    -- | Logistic regression model
    logRegr
      :: (Observable env "y" Bool
       , Observables env '["m", "b"] Double)
      => [Double]
      -> Model env rs [Bool]
    logRegr xs = do
      -- | Specify the distributions of the model parameters
      -- mean
      m     <- normal 0 5 #m
      -- intercept
      b     <- normal 0 1 #b
      -- noise
      sigma <- gamma' 1 1
      -- | Specify distribution of model outputs
      let sigmoid x = 1.0 / (1.0 + exp((-1.0) * x))
      ys    <- foldM (\ys x -> do
                        -- probability of event occurring
                        p <- normal' (m * x + b) sigma
                        -- generate as output whether the event occurs
                        y <- bernoulli (sigmoid p) #y
                        return (ys ++ [y])) [] xs
      return ys
    

    The Observables constraint says that, for example, "m" and "b" are observable variables in the model environment env that may later be provided a trace of observed values of type Double.

    Calling a primitive distribution such as normal 0 5 #m lets us later provide observed values for "m" when executing the model.

    Calling a primed variant of primitive distribution such as gamma' 1 1 will disable observed values from being provided to that distribution.

  2. Execute a model under a model environment, using one of the Inference library functions.

    Below simulates from a logistic regression model using model parameters m = 2 and b = -0.15 but provides no values for y: this will result in m and b being observed but y being sampled.

    simulateLogRegr :: Sampler [(Double, Bool)]
    simulateLogRegr = do
      -- | Specify the model inputs
      let xs  = map (/50) [(-50) .. 50]
      -- | Specify the model environment
          env = (#y := []) <:> (#m := [2]) <:> (#b := [-0.15]) <:> nil
      -- | Simulate from logistic regression
      (ys, envs) <- SIM.simulate logRegr env xs
      return (zip xs ys)
    

    Below performs Metropolis-Hastings inference on the same model, by providing values for the model output y and hence observing (conditioning against) them, but providing none for the model parameters m and b and hence sampling them.

    -- | Metropolis-Hastings inference
    inferMHLogRegr :: Sampler [(Double, Double)]
    inferMHLogRegr = do
      -- | Simulate data from log regression
      (xs, ys) <- unzip <$> simulateLogRegr
      -- | Specify the model environment
      let env = (#y := ys) <:> (#m := []) <:> (#b := []) <:> nil
      -- | Run MH inference for 20000 iterations
      mhTrace :: [Env LogRegrEnv] <- MH.mh 20000 logRegr (xs, env) ["m", "b"]
      -- | Retrieve values sampled for #m and #b during MH
      let m_samples = concatMap (get #m) mhTrace
          b_samples = concatMap (get #b) mhTrace
      return (zip m_samples b_samples)
    

    One may have noticed by now that lists of values are always provided to observable variables in a model environment; each run-time occurrence of that variable will then result in the head value being observed and consumed, and running out of values will default to sampling.

    Running the function mh returns a trace of output model environments, from which we can retrieve the trace of sampled model parameters via get #m and get #b. These represent the posterior distribution over m and b. (The argument ["m", "b"] to mh is optional for indicating interest in learning #m and #b in particular).

  3. Sampler computations can be evaluated with sampleIO :: Sampler a -> IO a to produce an IO computation.

    sampleIO simulateLogRegr :: [(Double, Bool)]